Computing device



Feb. 10, 1948. G. A. MoRToN Erm. 2,435,841

COMPUTING DEVICE Filed aan. 5, 1944 s sheets-sheet 1 e i ri,

' mie/# +300 p- W L ze 3 4 29 [00 :inventors GEURGE Hmonmn L* 7'0 20 3? LEsuE E. FLORY ng Gttorneg Feb. 10, 1948.

/MPZ/L 55 GEN.

G. A. MoRToN ETAL 2,435,841

COMPUTING DEVICE Filed Jan. 5, 1944 6 Sheets-Sheet 2 i 7o Wir/mz I, 5j i ffzfz'aif nwentor;

GEORGE H. moRTon LEfu E. FLoRg 'l ttorheg Feb, l0, 1948. v G. A. MoRToN ETAL 2,435,841

COMPUTING DVICE Filed Jan. 5, 1944 6 Sheets-Sheet 3 Srwentors GEORGE H. mamon a? LESLHI- E. FLORY nu Qttorneg Feb. 10; 1948.

G. A. MQRTQN ETAL oMPU'rING DEVICE' 6 Sheets-Sheet 4 Filed Jan. 5, 1944 oom+ Snuentors GEURGE H moRTUn 31 LESLIE E. FLoRy a Gttorneg d D V @tm w wknkw Feb. l0, 1948. G. A. Mo RToN ET AL COMPUTING DEVICE e sheets-sheet 5 Filed Jan. 5, 1944 Summers y NR mL HF E GL oN..

, .3 M Gttorneg -coMPu'LfING DEVICE Filed Jan. 5. 1944 6 Sheets-Sheet 6 :inventors GEORGE Fl moRTon LE/LIE EFLURY Patented Feb. 10, 1948 IUNITED STATES PATENT OFFICE comme pavrca .George A. Morton and Leslie E. li'lory, Princeton.

N. J., assigner: to Radio Corporation oi America, a corporation oi Delaware application January/s. 1944. semi No. sums (ci. zas-s1) quired to determine time of flight, gun elevation and the like consists basically of determining the value of the function and its rate of change with respect to the two variables at a number of discrete points and interpolating between these points. In accordance with the present invention, matrices are used for evaluating the re` quired quantities, and the fundamental elements containing the matrices for generating impulse number trains representing the necessary quantities are cathode-ray tube, similar to the monoscope utilized in television technique.

The monoscope consists of an electron gun, deflection means and a special screen or target which is connected to an external signal lead. These elements are enclosed in an evacuated envelope. Information is recorded on the special screen in the form oi' fine lines of carbon or the like, having a diil'erent secondary electron emission rate from the screen background which may consist of aluminum or an equivalent material. As the electron beam sweeps across the screen, a current pulse due to the change in secondary electron emission is generated each time a line is crossed. Pulses formed in this way are ampliiled and applied to a totalizing device.

The screen may be similar to a sheet of crosssection paper, in that it is divided into squares so that the vertical and horizontal positions of the squares represent the variables and u. Information is recorded in the squares in the form of lines representing binary numbers. Two types of lines are used. a narrow line for digit zero (0) and a wide line for digit one (1). The widthof the electron beam is made just small enough to resolve the narrow lines. Consequently, the output pulses are ofthe same width but differ in amplitude, a large amplitude representing 1 and a small amplitude representing 0. When the electron beam sweeps across such a groupof lines, potentials representative ofa series of dig its are developed.

The beam is normally biased to .thelowerleft hand corner ofthe screen, is deflected Aupwardly 'into alignment with the selected Arow. of squares amount corresponding to the i rows of squares: in other words, to the horizontal row of matrix squares containing the data pertinent to the `coarse point Y1. For this step. it is arranged that the vertical deflection is linearl and that Vae-,V1 volts are applied to the deiiecting electrodes, Vo being the voltage required to deilect the beam from the center to the bottom oi the matrix pattern, andVi the voltage required to move the beam one'row vertically. 'I'he beam is then deflected horizontally to the beginning of the square corresponding to the coarse point xi. Since here the beginning of the recorded number must be known with considerable accuracy, it is not satisfactory to depend upon linearity of deilection. Instead. thin straight vertical wires are stretched across the screen just .ahead of the squares for indexing the horizontal deilection.

'I'he signal from the selected square of the screen is in the form of potentials representative of thesuccessive digits of the binary number recorded on that particular square. These potentials are ampliiled and then divided into stepping pulses (one for each digital position) and impulses corresponding to the l digital positions where 1 appears in the\recorded number. The stepping pulses are utilied to control the operation of a totalizing device, wherein the product of the recorded number and the fine value of the variable is established, the pulses corresponding to the digit 1 being combined with this ne value to establish the desired product.

In the illustrated form o! the invention, three.

matrices are utilized to evaluate the function completely. The invention, however. does not necessarily involve three monoscope tubes, since if the resolution requirements are not too great,

`more than one matrix may be placed on a single screen. For convenience in understanding. however, separate cathode ray tubes for each matrix are shown.

Important objects of the invention are to provide a function generator having various terms of the function or factors of these terms record# determined one of such areas, and at another speed to scan such area, and to provide means whereby these .various factors and terms are combinedl to producethe 4desired function.

The invention, will be better understood from the followingdescription considered in connection with the accompanying drawings, and its scope is indicated by the appended claims.

Referring to the drawings:

Figure 1 is a block diagram illustrating thc` l fleeting system which includes the impulse generator. the switch SV. the vertical deflection generator DV and the coarse set-up device Y of Fig. 1,

Fig. 4 is a wiring diagram of that part of the horizontal deflecting system including the switch SH and the coarse X set-up device of Fig. 1,

Fig. 5 is a front elevation of the matrix and the horizontal indexing wires,

Fig. 6 is an enlarged view of one corner of the screen of Figure 6, showing the lines corresponding to the different digital positions of the recorded number, the wide lines representing the digit 1 and the narrow lines representing the digit 0,

Fig. '7 is a wiring diagram of the amplifier and other elements enclosed in the box Ai of Fig. 1,

Fig. 8 is a wiring diagram illustrating part of the connections of the totalizing device appearing at the upper right-hand corner of Figure 1, and

Fig. 9 is an enlarged diagram of the totalizer.

In considering Figs. 1, 5 and 6, it should be lremembered that the horizontal indexing wires are shown as perpendicular to the paper in Fig. 1

. and as extending lengthwise of the paper in Figs.

5 and 6, and that these wires are all connected through a common output terminal to other parts of the device as hereinafter explained.

If the function to be evaluated is the operation of the device involves (1) separation of the variables :c and y into the coarse points .n and 1u and into the flne points Az and and the horizontal indexing wires il.` These wires i1 are connected to a common terminal Il andthence to the corresponding coarse X set-up device and to one of the four terminals of the switch SH. Other terminals oi' the switch SH are connected respectively to the horizontal defiection generator DH, to a control element of the circuit AI and to the coarse X counter. The horizontal deflecting systems of all three cathode ray devices I0, I l and l2 are similar to that described.

A single vertical deflecting system is provided for all three devices I 0, il and i 2. It includes a switch SV having four terminals which are connected respectively to one lead of a sequence switch, to an impulse generator and to opposite ends of the coarse Y set-up device.

Ay, (2) evaluation of the quantities fu, au and bu v from the monoscopes and (3) two multiplications and three additions. Numbersrepresenting the coarse points of the two variables are set up in the coarse u and coarse a: set-up devices which operate, together with other parts of the device, to select the particular square on which the quantity fu, au or bu is recorded. Numbers representing the fine points of the two variables are set up on the set-up devices A: and Ay which cooperate with the elements Ai-Tl, A2-T2 and Aft-T3 to establish the desired function in the totalizer. The various steps in the operation are initiated by a series of starting pulses applied through a sequencing switch ilrst to the vertical deectors of the three cathode ray tubes, second to the horizontal deflectors of the first cathode ray tube, third to the horizontal deflectors of the second cathode ray tube and fourth to the horizontal defiectors of the third cathode ray tube. Aside from the setting up of the coarse and flne points of thel variables and the application of the starting pulses, the operation of the computer is altogether automatic.

Referring to Fig. 1, the function generator includes three cathode ray devices I0, Il and I2, each of which is provided with an electron gun i3 for forming a beam of electrons, a pair of electrodes Il for deflecting the beam in a. vertical direction, a pair of electrodes I5 for deflecting the beam in a horizontal direction, a screen or target I8 upon the successive squares or areas of which are recorded the successive values of the quantities indicated at the right of thesel targets.

ment A2 impulses representative of the digits 1 l of the quantity recorded on the screen of the device il are supplied to the transfer element T2, wherein they are combined with the fine Y count AY and .from which these combined quantities are supplied to the totalizer A-B. Impulses representative of the digits 1 of the quantity recorded on the screen of the device i2 are supplied through the element A3 and the transfer element T3 to the totalizer A-B. Also supplied to the totalizer A-B through each of the elements AI, A2 and A3 are stepping pulses representative of the digital positions of the numbers representing the different recorded quantities a(xy) or au, b(.'cy) or bu and f(:ry) or fu.

In the operation of the function generator of Fig. l, the fine :c and y counts are flrst set up on the devices AX and AY and there is established in the coarse X andl Y devices numbers which are dependent on the values of X and Y respectively. These dependent numbers are established on each coarse set up device by setting up a number which is equalto the highest count of the device minus the value of the variable. For example, if the coarse X value is and the coarse X set-up device has flve units, the number is set up. 'Ihis is 1 less than Vthe complement of the coarse X value 00110 and is just sunicient to flll the set-up device which is turned forward to zero in response to the addition of the complete complement oi' 00110(=11010 A starting signal is then applied through the terminal I9 of the sequence switch to the switch SV, thus starting the vertical deflection of the beam and adding to the count of the coarse Y counter at each step in the deflection until this counter is turned forward to zero and the beam stops at the horizontal row of areas containing the area on which the pertinent data is recorded.

A starting pulse is then applied through the terminal 20 of the sequence switch to the horizontal deflection generator DH with theresult that the beam is deflected horizontally at a relatively high speed across the horizontal indexing wires Il. As the beamcrosses each wire, there is produced a pulse by which l is added to the number set up in the coarse X set-up device until this device is turned 'forward to zero, when the switch SH is actuated to put the element AI into operating condition and to slow down the ment AI are restored to their initial condition,

with the exception that the corresponding coarse X count is now zero.

The operations of the devices il and I2 for storing the quantities bmw/iu and fury) in thc totalizer are similar to that Just described, with the exception that a starting pulse is applied throughterminal 2| of the sequence switch to g the horizontal deflection generator DH of the device II and through the terminal 22 of the sequence switch to the deflection generator DH oi the device I2.

The exact manner in which these various effects are produced will be better understood from a consideration of the wiring diagrams of the horizontal deflection generators DH (Fig. 2) the vertical deflection system (Fig. 3), the horivzontal deilection system (Fig. 4), the circuits AI,

A2 and A3 for producing the stepping and counting pulses (Fig. 7) and totalizer A--B (Fig. 8), and the block diagram of the totalizer (Fig. 9).

The horizontal deflection generator of Fig. 2 includes a capacitor 22, which is charged through a charging tube 24 in parallel with resistor R., and is discharged through a tube 25 in response to a starting signal supplied from the sequence terminal switch'terminal 2l through a direct current amplifier 26. The resulting change in potential is applied through a coupling capacitor 2l to the single-ended push-pull amplifier stage 28-29, and thence to the horizontal deflecting electrodes I of the cathode ray device IIJ, thus defiecting the beams transversely of the indexing wires to the screen area on which the pertinent data is recorded. When the beam reaches the index wire immediatly preceding this area, the potential of the control grid of the charging tube 24 receives through a lead 20 a negative potential which cuts ofi.' the plate current in tube 24 so' the capacitor 23 is now charged only through resistor R. This slows down the rate of charge and therefore the speed at which the beam is deflected. All the horizontal deflection generators DH of Fig. 1 are identical with the exception that the starting impulses are applied through diiierent terminals of the sequencing switch and at successive times.

The complete horizontal deiiection system of each of the devices Il, II and I2 is illustrated in Fig. 4 wherein the horizontal deflection generator of Fig. 2 is indicated as a block indicated by the reference characters DH.

Thus, the switch SH (enclosed by dotted lines) is a multivibrator or trigger circuit of well known type which includes a pair of electron discharge devices 3| and 32 interconnected iny the usual manner.

The coarse X set-up device likewise consists of a -number of such trigger circuit units including pairs of interconnected electron discharge devices 33-34, 85-35, 31-38, some of the intermediate units being shown as blocks land all the various units being coupled together through capacitors 39 to 42. The conductive condition of the tubes of each unit determine whether that unit is in a binary 1 or a binary 0 condition.

Thus. when the first tube 23 of the fiist unit il inl a conductive condition and the second tubo 34 of this unit is in a non-conducting condition theunit as a whole is in a binary l condition. When thetube 341s conducting and the tube 8l is non-conducting ythe unit is in a binary zero condition. The same is true of all the other units of the coarse X counter.

Assuming all the units to be in a binary zero condition, the set-up device is turned to zero and a number equal to N-Xi, (where N is the number represented by all the units and X1 is the coarse X count) is set up by applying negative pulses through the terminals 42 to 4I to the units which are to be turned to a binary 1 condition. n

Impulses from the horizontal index wires I1 are added to thiscount through the lead 4l until the coarse'X set-up device is full and the count reaches N when the set-up device turns to zero.

These negative pulses from the horizontal index wires are also applied through a capacitor to the control grid of the tube 3| thereby ensuring that this tube is non-conducting and the tube I2 is conducting so that the negative potential of a battery 49 connected in the lead 3|! is neutralized by the potential drop of the cathode resistor 5I) of the tube 32.

When the set-up device clears or turns to zero, a negative pulse transmitted through a capacitor 5I switches current from the tube `32 to the tube II thereby permitting the negative potential of the battery 49 to be applied to the lead 30 for slowing down movement of the beam. At the same time, the positive potential drop of the cathode resistor 52 of the tube 3i neutralizes the negative potential of a battery 53 connected in the control lead of the circuit AI thus permitting signals to be `transmitted through this circuit.

The vertical deilection system of Fig. 3 includes a switch SV comprising the trigger circuit tubes 54 and 55 and a control tube 56. Positive pulses are applied from a generator 51 through a capacitor I8 to the control grid of the tube 56 which is capable of delivering negative pulses to the coarse Y set-up device and to the deflection generator DV only when the tube 54 is conducting and a 1pivsive potential drop exists in its cathode resis- Assuming the tube 54 to be conducting, the negative pulses supplied through the tube Il function to add to the count set-up in the coarse Y set-up device and at the same time (through the amplifier 60 and rectifier 6I) to increase the charge of a capacitor 52. As the charge of this capacitor increases. the voltage between the vertical deilectors I4 is increased and the beam is moved to the line of areas containing the pertinent information. Then the coarse Y counter clears and thereby transmits 'a positive impulse to the control grid of the tube 55 thus transferring current from the tube 54 to theptube 55 and biasing of! the control tube 56. The system is restored to its initial condition by the application of a positive pulse to the lead 63.

Figs. 5 and 6 show various details of the screens and horizontal index 4wires of the devices I0. II and I2 of Fig. 1. These details are obvious from what has been said in connection with previous gures.

The circuit of Fig. 'l (element AI, A2 or A3 of Fig. l) includes an input terminal 5 4 which is connected to the screen Il and a switching terminal Il which is connected to the corresponding 7. terminaloftheswitchBH (Figs. 1and4). The operation of the switching Signal to prevent operation of the circuit until the coarse X set-up device has cleared (turned forward to zero) is obvious from the previous explanation.

When the coarse X counter has cleared, e area containing the pertinent data is scanned a a relatively slow speed and the resulting signals are applied through the lead Il to the control electrode of an amplifier i and are further amplined by the amplifiers and Il. Prom the output of the amplifier 68, the signals are supplied to two paths, one of which includes a limiter unit 69 and a diiferentiator unit Il for producing the stepping pulses and the other of which includes an amplifier unit 1I, a clipper unit 12 and a diiferentlator unit 13 `for providing the counting pulses which represent the digits 1 of the recorded data. The character of the signal pulses at each stage of their progress through the circuits is shown above the circuits and is readily understood in view of the fact (previously explained) that each pulse represents a digital position in a binary number, the high amplitude.

pulses represent the digit 1 and the low amplitude pulses represent the digit 0. The stepping pulses appearing at the output terminal 14 are applied to the corresponding terminal of the totalizer and the counting pulses appearing at the terminal 'I5 are delivered to the corresponding terminal of the transfer element Tl, T2 or T3.

Fig. 8 illustrates the wiring of two units of the transfer element and two units of the totalizerl which ls used successively to store or accumulate the quantities fury), ami/)Az and bwl/)Ay so that at the end of these successive operations its condition indicates the desired function A block diagram of the totalizer is shown in Fig. 9.

At this point, it should be understood (1) that the trigger circuit units of the switches SH and SV are of the type in which only one of the cross-connected tubes ls conducting at a time and current is switched from one tube to the other by the application of a negative pulse either to the grid of the conducting tube or to the upper terminals of the anode resistors of the two tubes, (2) that the coarse x, Ax coarse u and Ay set-up devices all include similar trigger circuit units which are connected in cascade as indicated at the top of Fig. 4, (3) that the units A of the totalizer include a number of trigger circuit units, and (4) that the units B of the totalizer are similar to those of the units A with the exception that they are of the slide-back type, i. e.. the grid resistance of the right hand tube is made higher than that of the left hand tube so that a negative pulse applied to the grid of the right hand tube transfers current to the left hand tube for a predetermined very short time after which current is automatically returned to the right hand tube. These various set-up circuits are more fully disclosed and claimed in our co-pend ing application Serial No. 473,146, filed January 21, 1943, now Patent No. 2,404,047.

The circuit of Fig. 8 includes a number of transfer tubes 16, 11, etc., there being one such tube for each digital position of the number Az, All or one for fury) as the case may be. It also includes a trigger circuit unit A1, Az, etc., for each digital position of the number representing the function F=f(:ry) +Mw) Az-l-biy) Ay. Connected between the A units are the slide-,back

units Bi. Bz, etc.. which transfer a digit 1 (from one A unit representing one digital position to another A unit representing the next higher dit ital position) when the lower digital A unit changes from a binary 1 to a binary 0 condition. Potentials representative of the quantities Az, AI and a positive potential for the transfer tube o! f(.'cy) are applied through the leads 1l, 1I, etc.. stepping pulses (one for each digital position) are applied through the lead 'I4 and pulses corresponding to the digits in the number recorded on the monoscope screen are applied to the lead 15, Binary digits 1 and 0 are placed above the tubes of the A units to indicate the binary oondition of the unit. Thus, when the right hand tube is conducting, the unit is in a binary zero condition and its indicator 80 is unlighted and, when the left hand tube is conducting. the unit is in a binary one condition and its indicator Il is lighted.

Assuming that the totalizer units A1 and A: represent successive digital positions and that unit Ai is in a binary one condition with its left hand tube conducting, the application of a negative pulse to the A1 unit will convert the unit to a binary zero condition thereby applying a negative pulse to the grid of the right hand tube of the slide-back unit B1 and temporarily transferring current from its right hand tube to its left hand tube. When right hand tube again becomes conducting a negative pulse is transferred through the coupling capacitor 82 to the anode resistors of the unit Az. If this unit is in a binary zero condition, all that happens is the transfer of current to its left hand tube thereby converting it to a binary one condition. If it is in a binary one condition, it is converted to a binary zero condition and a negative pulse is applied through a capacitor 83 to the control grid of the right hand tube of the slide-back unit Bz, thereby temporarily transferring current to its left hand tube and when the current returns to its right hand tube, applying through a capacitor Il a negative pulse whereby a digit 1 is transferred to the A; unit (see Fig. 9). This process continues throughout the successively higher digital position units of the totalizer, as will be explained more fully in connection with the consideration of a specific calculation as performed by the com'- puters. Between these transfers of DOtentials from the leads 18, 19, etc., a negative pulse is applied through the lead l5 and the capacitors Il. It, etc.,4 to the grid of the left-hand tube of each A unit for stepping the accumulated number to the next highest digital position. How this is accomplished is apparent if a number 000000001010 be considered as established in the totalizer. Under these conditions, the application of a negative pulse to the left hand grids of all the A units has no effect on a unit which is in a binary 0 condition but converts all units in a binary 1 condition to a binary 0 condition so that all the ones in the number are transferred to the next higher digital position and the number 000000010100 appears in the totalizer.

If Ax=1101, mm1/)=1010, Ay=1001, b(1lz)= 1110 and f(u.1:)=101l as indicated on Fig. 9, the

. computation of the function F=f (xy) +Mw) Az+ Nrw/iu is performed as indicated by the following tabulation in which the total number of steps in the operation are indicated in the rst column, the number in the totalizer at each step is indicated in the second column, the steps at which numbers arev passed by the transfer elements TI,

T2 or T3 are indicated in the third column. and

1. The combination oi means for forming a beam oi electrons, means having successive areas.

9 the stepping pulses are indicated in fourth col- 4 umn.

Stop 'Irsnsior sgml Remarks l mausi i 1 :his period o 9 Ajdusting totalir 1 l y 1 assiette, l 1 this period 0 9 Adlustlng totalizer l I wir: als

l l dugng this poriod 1 Consideration of this tabulation in connection with Fig. 9 makes clear the operation of the computer. number 1101 is transferred to the totalizer units A once for each digit 1 in the number 1010 and in the proper digital positions to produce the product 1l01 1010=10000010, which appears backward as read from the front of the totalizer and contains eight digital positions.

Since this product contains eight digital positions and the totaiizer is shown as containing twelve digital positions, it is necessary that the number 10000010 be moved nine digital positions to bring it into the proper position for adding the product of 1001x1110. This is done by adding nine zero characters to monoscope screen area on which the number 1010 is recorded or by supplying these nin'e negative impulses from an impulse generator 81 such as that disclosed in our copending application Serial No. 473,146, filed Jan- Thus, during the iirst seven steps, the

upon which are recorded diiierent values of a predetermined quantity. a set-up device, means for moving said beam to select and scan a predetermined one of said areas, and means responsive to said beam during the scanning ot said selected area for deriving the product oi the value recorded on said selected area and a value established in said set-up device.

2. The combination of means for forming a beam of electrons, means having successive areas upon which are recorded dinerent values ot a predetermined quantity, a set-up device, means for moving said beam at one speed to select a predetermined one of said areas, and for moving saidbeam at another speed to` scan said selected area, and means responsive to said beam during the scanning of said selected area for deriving the product o! the value recorded on said selected area and a value established in said set-up device.

3. The combination of means for forming a beam of electrons, means having successive areas upon which are recorded diiierent values of-a predetermined quantity. a fine point set-up device, means including a coarse point set-up device i'or moving said beam to select and scan a predetermined one of said areas, and means responsive to said beam during the scanning oi' said selected area for deriving the product of the l value recorded on said selected area and a value predetermined quantity, a ilne point set-up deuary 21, 1942.- Such a generator operates automatically in response to a potential from the switch SH (Fig. 1) to deliver any desired nums ber of negative pulses. When these nine pulses have been applied, the highest digit of the number 100000101 is in the unit A5, the next four lower digits of this number are in the units A4, Az, Az and A1 and the three lower digits of this number are in the units A12, A11 and Aw. the lowest digit being the unit A10.

During the steps 9 to 15, the number 1001 is transferred to the totalizer units A once for each digit 1 in the number 1110 and in the proper digital positions to produce the sum of the products 1l01 1010+1001 1110=100000000.

The number 100000000 is then stepped along as before to put this number in the proper position for adding the number 1011. This is done during steps 17 to 20 and the result is the sum f(:ry) +a(zy)A+b(1/)Ay The invention thus involves (l) the provision oi' means for deriving the product oi two numbers one of which is set up on a set-up device n vice, a coarse point set-up device, indexing means between certain of said areas for adding to a value established in said coarse set-up device, a horizontal deilection generator, a switch responsive toclearing of said coarse set-up device for operating said generator to move said beam to scan one of said areas, and means responsive to said beam during the scanning of said area for deriving the product of the value recorded on said scanned area and a value established in said tine point set-up device.

5. The combination of a plurality oi' means each having successive areas `upon which are recorded values of a 'predetermined quantity which is different in the case of each of said means, a different iine point set-up device associated with each of said means, a different coarse point set-up device associated with each of said means, a coarse set-up devices common to all of said means, means responsive to a first oi said coarse set-up devices and said common set-up device for selecting and scanning a predetermined area of a rst of said means, means responsive to a second of said coarse set-up devices and said common set-up device for selecting and scanning a predetermined area of a second of said means. and means responsive to said selecting and scanning means during the scanning oi' said areas for deriving thesum of the product of the value recorded on the iirst of said selected areas multiplied by a value established in a tlrst of said iine point set-up devices and the product of the value recorded on the second of said selected areas multiplied by a value established in a second of said nne point set-up devices.

6, The combination ci a plurality of means each having successive areas upon which `are recorded values of a predetermined quantity which is 'different in the case of each of said means, different fine point set-updevice associated withtwo of said means, a different coarse point set-up device associated with each of said means, a coarse set-up device common to all of said means, means responsive to a first of said coarse set-up devices and said common set-up device for selecting and scanning a predetermined area of a first of said means, means responsive to a second of said coarse set-up devices and said common set-up device for selecting and scanning a predetermined area of a second of said means, means responsive toa third of said coarse set-up devices and said common set-up device for selecting and scanning a predetermined area of a third of said means, and means responsive to said selecting and scanning .means during the scanning of said 'areas for deriving the sum of the product of the value recorded on the first of said selected areas multiplied by a value established in a first of said ne point set-up devices and the product of the value recorded on the second of said selected areas multiplied by a value established in a second ot said ne point set-up devices and for deriving a mathematical result dependent on the value recorded on said third selected area and said sum.

7. The combination of means for forming a plurality of electron beams,- a plurality of means upon successive areas of which are recorded different values of a predetermined quantity which is dierent in the case of each of said means. a different set-up device associated with each of said means, means for moving each of said beams to scan a predetermined one of said areas, means responsive to said beam during the scanning of said areas for deriving the product of the value recorded on each selected area and a value established in its associated set-up device and for deriving the sum of said products.

8. A function generator including means for producing a plurality 'of electron beams, a plurality of means each having successive areas on which are recorded successive values of one factor Y `of a ditl'ere'nt term of the function to be genf erated. a plurality of set-up units for storing the other factors of said terms, means for moving one of said beams to select and scan a ilrst predetermined area of a first of said successive area means, means for moving another of said beams to select and scan a second predetermined area of a second 9. A function generator including a plurality a said areas for combining said factors to completethe incomplete terms of said function and for combining the values of the terms thus completed with the value of the term completely recorded on one of said selected and scanned areas.

10.A The combination of means forming a beam of electrons, means having groups of successive areas upon which are recorded diiierent values of a predetermined quantity. an impulse generator. means responsive to impulses delivered from said generator for moving said beam to select a predetermined one of said groups, means for moving said beam to select and scan a predetermined area of said selected group. a set-up device, and means responsive to said beam during the scanning of said selected area for deriving the product of the value recorded on said selected area and a value established in said set-up device.

11. The combination of means forming a beam of electrons, means having successive areas upon which are recorded different values of a predetermined quantity, a ne point set-up device, a coarse point set-up device, means for moving said beam, indexing meansilocated between certain of said areas and responsive to movement of said beam for operating said coarse set-up device to select a predetermined one of said areas, and means responsive to said beam during its movement across said selected area for deriving the product of a value recorded on said selected area and a value established in said ilne point set-up device.

12. The combination of means forming a beam of electrons, means having successive areas upon which are recorded different values of a predetermined quantity, means for moving said beam to scan different ones of said areas and to produce pulses in groups each representative of a different one oi.' said values, and means responsive to said beam during the scanning of each of said areas for establishing a representation of the group of pulses by which its recorded value is represented.

GEORGE A. MORTON. LESLIE E. FLORY.

` REFERENCES CITED The following references are of record in the 00 ille of this patent: f

VUNITED STATES PATENTS Number 

